Breast Carcinoma After Ocrelizumab Therapy in Multiple Sclerosis Patients: A Case Series and Literature Review.

Ocrelizumab is a humanized CD20 monoclonal antibody which was approved for management of Relapsing Remitting Multiple Sclerosis (RRMS) and Primary Progressive Multiple Sclerosis (PPMS) in 2017. We present 2 patients, a 67-year-old woman with history of PPMS and a 42-year-old woman with RRMS, who were started on ocrelizumab and were diagnosed with invasive ductal cell breast carcinoma after 2 years of ocrelizumab infusion followed by discontinuation of the drug. Large trials conducted for ocrelizumab showed malignancies in a total of 4 cases with RRMS in OPERA 1 trial conducted over 2 years from 2011 to 2013 (breast cancer, renal cell carcinoma, and melanomas) and in 11 cases with PPMS seen in ORATORIO trial conducted in 2017. There are currently no other published case reports of breast cancer in setting of ocrelizumab use for MS outside of large trials on literature review.

Upregulation of nAChRs and Changes in Excitability on VTA Dopamine and GABA Neurons Correlates to Changes in Nicotine-Reward-Related Behavior.

Previous reports indicate that nicotine reward is mediated through α4ß2*, α6ß2*, and α4α6ß2* nicotinic acetylcholine receptors (nAChRs; * indicates that additional nAChR subunits may be present). Little is known about α4α6ß2* nAChR involvement in reward and reinforcement because of a lack of methods that allow the direct investigation of this particular nAChR subtype. Here, we use male and female mice that contain α4-mCherry and α6-GFP nAChR subunits to show that concentrations of nicotine sufficient to evoke reward-related behavior robustly upregulate α4* and α4α6* nAChRs on midbrain dopamine (DA) and GABA neurons. Furthermore, the extent of α4α6* nAChR upregulation on ventral tegmental area (VTA) DA neurons aligns with the magnitude of nicotine reward-related behavior. We also show that the upregulation of nAChRs is accompanied by a functional change in firing frequency of both DA and GABA neurons in the VTA that is directly linked to nicotine reward-related behavior.

Why flavored vape products may be attractive: Green apple tobacco flavor elicits reward-related behavior, upregulates nAChRs on VTA dopamine neurons, and alters midbrain dopamine and GABA neuron function.

While nicotine is the primary addictive component in tobacco products, additional flavors have become a concern with the growing popularity of electronic nicotine delivery systems (ENDS). For this reason, we have begun to investigate popular tobacco and ENDS flavors. Here, we examined farnesol, a chemical flavorant used in green apple and fruit flavors in ENDS e-liquids, for its ability to produce reward-related behavior. Using male and female 3-6 month old C57BL/6 J mice and farnesol doses of 0.1, 1, and 10 mg/kg we identified a sex-dependent effect in a conditioned place preference assay: farnesol-alone produces reward-related behavior in only male mice. Despite this sex-dependent effect, 1.0 mg/kg farnesol enhances locomotor activity in both male and female mice. To understand farnesol's effect on reward-related behavior, we used whole-cell patch-clamp electrophysiology and confocal microscopy to investigate changes in putative dopamine and GABA neurons. For these approaches, we utilized genetically modified mice that contain fluorescent nicotinic acetylcholine receptors (nAChRs). Our electrophysiological assays with male mice revealed that farnesol treatment increases ventral tegmental area (VTA) dopamine neuron firing frequency and this may be due to a decrease in inhibitory tone from GABA neurons. Our microscopy assays revealed that farnesol treatment produces a significant upregulation of α6* nAChRs in male mice but not female mice. This was supported by an observed increase in α6* nAChR function in additional electrophysiology assays. These data provide evidence that popular tobacco flavorants may alter smoking-related behavior and promote the need to examine additional ENDS flavors.

N-Myc overexpression increases cisplatin resistance in neuroblastoma via deregulation of mitochondrial dynamics.

N-Myc is a global transcription factor that regulates the expression of genes involved in a number of essential cellular processes including: ribosome biogenesis, cell cycle and apoptosis. Upon deregulation, N-Myc can drive pathologic expression of many of these genes, which ultimately defines its oncogenic potential. Overexpression of N-Myc has been demonstrated to contribute to tumorigenesis, most notably for the pediatric tumor, neuroblastoma. Herein, we provide evidence that deregulated N-Myc alters the expression of proteins involved in mitochondrial dynamics. We found that N-Myc overexpression leads to increased fusion of the mitochondrial reticulum secondary to changes in protein expression due to aberrant transcriptional and post-translational regulation. We believe the structural changes in the mitochondrial network in response to N-Myc amplification in neuroblastoma contributes to two important aspects of tumor development and maintenance-bioenergetic alterations and apoptotic resistance. Specifically, we found that N-Myc overexpressing cells are resistant to programmed cell death in response to exposure to low doses of cisplatin, and demonstrated that this was dependent on increased mitochondrial fusion. We speculate that these changes in mitochondrial structure and function may contribute significantly to the aggressive clinical ph9enotype of N-Myc amplified neuroblastoma.

PKCζ Is Essential for Pancreatic ß-Cell Replication During Insulin Resistance by Regulating mTOR and Cyclin-D2.

Adaptive ß-cell replication occurs in response to increased metabolic demand during insulin resistance. The intracellular mediators of this compensatory response are poorly defined and their identification could provide significant targets for ß-cell regeneration therapies. Here we show that glucose and insulin in vitro and insulin resistance in vivo activate protein kinase C ζ (PKCζ) in pancreatic islets and ß-cells. PKCζ is required for glucose- and glucokinase activator-induced proliferation of rodent and human ß-cells in vitro. Furthermore, either kinase-dead PKCζ expression (KD-PKCζ) or disruption of PKCζ in mouse ß-cells blocks compensatory ß-cell replication when acute hyperglycemia/hyperinsulinemia is induced. Importantly, KD-PKCζ inhibits insulin resistance-mediated mammalian target of rapamycin (mTOR) activation and cyclin-D2 upregulation independent of Akt activation. In summary, PKCζ activation is key for early compensatory ß-cell replication in insulin resistance by regulating the downstream signals mTOR and cyclin-D2. This suggests that alterations in PKCζ expression or activity might contribute to inadequate ß-cell mass expansion and ß-cell failure leading to type 2 diabetes.

Early and Late G1/S Cyclins and Cdks Act Complementarily to Enhance Authentic Human ß-Cell Proliferation and Expansion.

ß-Cell regeneration is a key goal of diabetes research. Progression through the cell cycle is associated with retinoblastoma protein (pRb) inactivation via sequential phosphorylation by the "early" cyclins and cyclin-dependent kinases (cdks) (d-cyclins cdk4/6) and the "late" cyclins and cdks (cyclin A/E and cdk1/2). In ß-cells, activation of either early or late G1/S cyclins and/or cdks is an efficient approach to induce cycle entry, but it is unknown whether the combined expression of early and late cyclins and cdks might have synergistic or additive effects. Thus, we explored whether a combination of both early and late cyclins and cdks might more effectively drive human ß-cell cell cycle entry than either group alone. We also sought to determine whether authentic replication with the expansion of adult human ß-cells could be demonstrated. Late cyclins and cdks do not traffic in response to the induction of replication by early cyclins and cdks in human ß-cells but are capable of nuclear translocation when overexpressed. Early plus late cyclins and cdks, acting via pRb phosphorylation on distinct residues, complementarily induce greater proliferation in human ß-cells than either group alone. Importantly, the combination of early and late cyclins and cdks clearly increased human ß-cell numbers in vitro. These findings provide additional insight into human ß-cell expansion. They also provide a novel tool for assessing ß-cell expansion in vitro.

Hepatocyte growth factor ameliorates hyperglycemia and corrects ß-cell mass in IRS2-deficient mice.

Insulin resistance, when combined with decreased ß-cell mass and relative insufficient insulin secretion, leads to type 2 diabetes. Mice lacking the IRS2 gene (IRS2(-/-) mice) develop diabetes due to uncompensated insulin resistance and ß-cell failure. Hepatocyte growth factor (HGF) activates the phosphatidylinositol 3-kinase/Akt signaling pathway in ß-cells without recruitment of IRS1 or IRS2 and increases ß-cell proliferation, survival, mass, and function when overexpressed in ß-cells of transgenic (TG) mice. We therefore hypothesized that HGF may protect against ß-cell failure in IRS2 deficiency. For that purpose, we cross-bred TG mice overexpressing HGF in ß-cells with IRS2 knockout (KO) mice. Glucose homeostasis analysis revealed significantly reduced hyperglycemia, compensatory hyperinsulinemia, and improved glucose tolerance in TG/KO mice compared with those in KO mice in the context of similar insulin resistance. HGF overexpression also increased glucose-stimulated insulin secretion in IRS2(-/-) islets. To determine whether this glucose homeostasis improvement correlated with alterations in ß-cells, we measured ß-cell mass, proliferation, and death in these mice. ß-Cell proliferation was increased and death was decreased in TG/KO mice compared with those in KO mice. As a result, ß-cell mass was significantly increased in TG/KO mice compared with that in KO mice, reaching levels similar to those in wild-type mice. Analysis of the intracellular targets involved in ß-cell failure in IRS2 deficiency showed Pdx-1 up-regulation, Akt/FoxO1 phosphorylation, and p27 down-regulation in TG/KO mouse islets. Taken together, these results indicate that HGF can compensate for IRS2 deficiency and subsequent insulin resistance by normalizing ß-cell mass and increasing circulating insulin. HGF may be of value as a therapeutic agent against ß-cell failure.

Hepatocyte growth factor/c-Met signaling is required for ß-cell regeneration.

Hepatocyte growth factor (HGF) is a mitogen required for ß-cell replication during pregnancy. To determine whether HGF/c-Met signaling is required for ß-cell regeneration, we characterized mice with pancreatic deletion of the HGF receptor, c-Met (PancMet KO mice), in two models of reduced ß-cell mass and regeneration: multiple low-dose streptozotocin (MLDS) and partial pancreatectomy (Ppx). We also analyzed whether HGF administration could accelerate ß-cell regeneration in wild-type (WT) mice after Ppx. Mouse islets obtained 7 days post-Ppx displayed significantly increased c-Met, suggesting a potential role for HGF/c-Met in ß-cell proliferation in situations of reduced ß-cell mass. Indeed, adult PancMet KO mice displayed markedly reduced ß-cell replication compared with WT mice 7 days post-Ppx. Similarly, ß-cell proliferation was decreased in PancMet KO mice in the MLDS mouse model. The decrease in ß-cell proliferation post-Ppx correlated with a striking decrease in D-cyclin levels. Importantly, PancMet KO mice showed significantly diminished ß-cell mass, decreased glucose tolerance, and impaired insulin secretion compared with WT mice 28 days post-Ppx. Conversely, HGF administration in WT Ppx mice further accelerated ß-cell regeneration. These results indicate that HGF/c-Met signaling is critical for ß-cell proliferation in situations of diminished ß-cell mass and suggest that activation of this pathway can enhance ß-cell regeneration.

Human pancreatic ß-cell G1/S molecule cell cycle atlas.

Expansion of pancreatic ß-cells is a key goal of diabetes research, yet induction of adult human ß-cell replication has proven frustratingly difficult. In part, this reflects a lack of understanding of cell cycle control in the human ß-cell. Here, we provide a comprehensive immunocytochemical "atlas" of G1/S control molecules in the human ß-cell. This atlas reveals that the majority of these molecules, previously known to be present in islets, are actually present in the ß-cell. More importantly, and in contrast to anticipated results, the human ß-cell G1/S atlas reveals that almost all of the critical G1/S cell cycle control molecules are located in the cytoplasm of the quiescent human ß-cell. Indeed, the only nuclear G1/S molecules are the cell cycle inhibitors, pRb, p57, and variably, p21: none of the cyclins or cdks necessary to drive human ß-cell proliferation are present in the nuclear compartment. This observation may provide an explanation for the refractoriness of human ß-cells to proliferation. Thus, in addition to known obstacles to human ß-cell proliferation, restriction of G1/S molecules to the cytoplasm of the human ß-cell represents an unanticipated obstacle to therapeutic human ß-cell expansion.

Cytoplasmic-nuclear trafficking of G1/S cell cycle molecules and adult human ß-cell replication: a revised model of human ß-cell G1/S control.

Harnessing control of human ß-cell proliferation has proven frustratingly difficult. Most G1/S control molecules, generally presumed to be nuclear proteins in the human ß-cell, are in fact constrained to the cytoplasm. Here, we asked whether G1/S molecules might traffic into and out of the cytoplasmic compartment in association with activation of cell cycle progression. Cdk6 and cyclin D3 were used to drive human ß-cell proliferation and promptly translocated into the nucleus in association with proliferation. In contrast, the cell cycle inhibitors p15, p18, and p19 did not alter their location, remaining cytoplasmic. Conversely, p16, p21, and p27 increased their nuclear frequency. In contrast once again, p57 decreased its nuclear frequency. Whereas proliferating ß-cells contained nuclear cyclin D3 and cdk6, proliferation generally did not occur in ß-cells that contained nuclear cell cycle inhibitors, except p21. Dynamic cytoplasmic-nuclear trafficking of cdk6 was confirmed using green fluorescent protein-tagged cdk6 and live cell imaging. Thus, we provide novel working models describing the control of cell cycle progression in the human ß-cell. In addition to known obstacles to ß-cell proliferation, cytoplasmic-to-nuclear trafficking of G1/S molecules may represent an obstacle as well as a therapeutic opportunity for human ß-cell expansion.

Loss of HGF/c-Met signaling in pancreatic ß-cells leads to incomplete maternal ß-cell adaptation and gestational diabetes mellitus.

Hepatocyte growth factor (HGF) is a mitogen and insulinotropic agent for the ß-cell. However, whether HGF/c-Met has a role in maternal ß-cell adaptation during pregnancy is unknown. To address this issue, we characterized glucose and ß-cell homeostasis in pregnant mice lacking c-Met in the pancreas (PancMet KO mice). Circulating HGF and islet c-Met and HGF expression were increased in pregnant mice. Importantly, PancMet KO mice displayed decreased ß-cell replication and increased ß-cell apoptosis at gestational day (GD)15. The decreased ß-cell replication was associated with reductions in islet prolactin receptor levels, STAT5 nuclear localization and forkhead box M1 mRNA, and upregulation of p27. Furthermore, PancMet KO mouse ß-cells were more sensitive to dexamethasone-induced cytotoxicity, whereas HGF protected human ß-cells against dexamethasone in vitro. These detrimental alterations in ß-cell proliferation and death led to incomplete maternal ß-cell mass expansion in PancMet KO mice at GD19 and early postpartum periods. The decreased ß-cell mass was accompanied by increased blood glucose, decreased plasma insulin, and impaired glucose tolerance. PancMet KO mouse islets failed to upregulate GLUT2 and pancreatic duodenal homeobox-1 mRNA, insulin content, and glucose-stimulated insulin secretion during gestation. These studies indicate that HGF/c-Met signaling is essential for maternal ß-cell adaptation during pregnancy and that its absence/attenuation leads to gestational diabetes mellitus.