Cellular control mechanisms

It is of interest to understand how new neurons incorporate themselves into the
existing circuitry of certain neuronal populations. One such population of neurons is that
which are born in the subventricular zone (SVZ) and migrate to the olfactory bulb where
they differentiate into granule cells. Another area of interest is the role of brain-derived
neurotrophic factor (BDNF) on the survival and overall health of these neurons. This
study aimed to test whether or not BDNF is a survival factor for adult-born granule cells.
Here were utilized a transgenic mouse model over-expressing BDNF under the α-
calcium/calmodulin-dependent protein kinase II (CAMKIIα) promoter, and tested its
effect on olfactory granule cells under sensory deprived conditions. Results from this
experiment indicated that there was no significant difference in cell death or cell survival when comparing transgenic and wild type animals. We concluded that BDNF is not a
survival factor for adult-born granule cells.

SK channels are small conductance Ca2+-activated K+ channels expressed throughout the CNS. SK channels modulate the excitability of hippocampal CA1 neurons by affecting afterhyperpolarization and shaping excitatory postsynaptic responses. Such SK-mediated effects on activity-dependent neuronal excitability and synaptic strength are thought to underlie the modulatory influence of SK channels on memory encoding. Here,the effect of a new SK1 selective activator, GW542573X, on hippocampal-dependent object memory, contextual and cued conditioning, and trace fear conditioning was examined. The results demonstrated that pre- but not post-training systemic administration of GW542573X impaired object memory and trace fear memory in mice 24 h after training. Contextual and cued fear memory were not disrupted. These current data suggest that activation of SK1 subtype-containing SK channels impairs long-term memory. These results are consistent with converging evidence that SK channel activation suppressed behaviorally triggered synaptic plasticity necessary for encoding hippocampal-dependent memory.

Transcription and translation of proteins are required for the consolidation of episodic memory. Arc, an effector immediate early gene, has been linked to synaptic plasticity following learning and memory. It is well established that the rodent hippocampus is essential for processing spatial memory, but its role in processing object memory is a point of contention. Using immunohistochemical techniques, hippocampal sections were stained for arc proteins in the CA1 region of the dorsal hippocampus in mice following two variations of the novel object recognition (NOR) task. Results suggest mice that acquired strong object memory showed significant hippocampal activation. In mice that acquired weak object memory, hippocampal activation was not significantly different from controls. Arc expression was also examined in other hippocampal sub-regions, as well as in the perirhinal cortex. These results suggest that the mice must acquire a threshold amount of object information before the hippocampal CA1 region is engaged.

The ubiquitin ligase Highwire is responsible for cell-autonomously promoting
synapse formation in the Drosophila Giant Fiber system. highwire mutants show defects
in synaptic function and extra branching at the axon terminal, corresponding to transient
branching that occur in the course of giant synapse formation during metamorphosis. The
MAP kinase pathway, including Wallenda and JNK/Basket, plus the transcription factor
Jun, act to suppress synaptic function and axon pruning in a dosage sensitive manner,
suggesting different molecular mechanisms downstream of the MAP kinase pathway
govern function and pruning. A novel role for Highwire is revealed, regulating the giant
fiber axon’s ability to respond to external cues regulated by Fos. When expression of the
transcription factor Fos is disrupted in the post-synaptic TTMn or surrounding midline
glia of highwire mutants, the giant fiber axons show a marked increase in axon overgrowth and midline crossing. However, synaptic function is rescued by the cell nonautonomous
manipulation of Fos, indicating distinct mechanisms downstream of Highwire regulating synaptic function and axon morphology.

The classic guidance molecules, Netrin and its receptor Frazzled (Fra), dictate the strength of
synaptic connections in the giant fiber system (GFS) of Drosophila melanogaster by regulating
gap junction localization in the pre-synaptic terminal. In Netrin mutant animals the synaptic
coupling between a giant interneuron and the jump motor neuron was weakened. Dye-coupling
between these two neurons was severely compromised or absent. These mutants exhibited
anatomically and physiologically defective synapses between the giant fiber (GF) and
tergotrochanteral motor neuron (TTMn). In cases where Netrin mutants displayed apparently
normal synaptic anatomy, half of the specimens exhibited physiologically defective synapses.
Dye-coupling between the giant fiber and the motor neuron was reduced or eliminated,
suggesting that gap junctions were disrupted in the Netrin mutants. When we examined the gap
junctions with antibodies to Shaking-B Innexin (ShakB), they were significantly decreased or
absent in the pre-synaptic terminal of the mutant GF. This data is the first to show that Netrin and
Frazzled regulate placement of gap junctions pre-synaptically at a central synapse. In the Drosophila Giant Fiber System, we demonstrate a mechanism that ensures the monoinnervation of two homologous motor neurons by two homologous interneurons. In a scenario where both interneurons could synapse with both motor neuron targets, each interneuron exclusively synapsed with only one target and the circuit functions at normal physiological levels. This innervation pattern depended on the ratio of netrin-to-frazzled expression. When Netrin was over expressed in the system, shifting the ratio in favor of Netrin,
both interneurons synapsed with both target motor neurons and physiological function was reduced. This resulted in the polyinnervationof a single target. In contrast, when Frazzled was over expressed in the system, one interneuron innervated both targets and excluded the remaining interneuron from making any synaptic contact. This resulted in a single interneuron mono-innervating both motor neurons and physiological function was mutant. The orphaned interneuron made no synaptic contact with either motor neuron target. Physiological function was only normal when the Netrin-Frazzled ratio was at endogenous levels and each GF monoinnervated one motor neuron. When we examined the gap junctions at this synapse in experimental animals, there was a significant reduction of gap junction hemichannels in the presynaptic terminal of axons that deviated from normal innervation patterns. While the synapse dyecoupled, the reduction in gap junction hemichannels reduced function in the circuit.

Exoribonucleases degrade RNA and are important in RNA metabolism and gene expression. Mycoplasma genitalium, a bacterium with the smallest genome known, has only one identified exoribonuclease, RNase R (MgR). In this work RNA degradation properties of purified MgR were examined. As observed in Escherichia coli RNase R (EcR) studies, MgR degrades poly(A), rRNA, and oligoribonucleotides in 3'--->5' direction, though its substrate specificity and optimal activity requirements vary. Interestingly, MgR is sensitive to 2-O-methylation stopping downstream of such modifications in native rRNA and synthetic oligoribonucleotides. MgR removes the 3' trailer sequence from a tRNA precursor of M. genitalium and generates products equal to the mature tRNA, demonstrating a role of MgR in tRNA maturation. The 3' terminal CCA sequence and the acceptor stem of tRNA play a role in determining the formation of such products by MgR. These results suggest multiple functions of RNase R in RNA metabolism in Mycoplasma.

The rodent hippocampus is critical for processing spatial memory but its contribution to non-spatial, specifically object memory is debated. The cognitive map theory of hippocampal function states that the hippocampus stores relationships of goal locations (places) to discrete items (objects) encountered within environments. Dorsal CA1 place cells were recorded in male C57BL/6J mice performing three variations of the novel object recognition paradigm to define "object-in-context" representation of hippocampal neuronal activity that may support object memory. Results indicate, (i) that place field stability is higher when polarizing environmental cues are provided during object recognition; (ii) hippocampal place fields remain stable throughout the novel object recognition testing without a polarizing cue; and (iii) time dependent effects on stability when objects were dissociated from the context. These data indirectly support that the rodent hippocampus processes object memory, and challenge the view that "object-in-context" representations are formed when mice perform novel object recognition task.

The lens is an avascular organ that focuses light onto the retina where neural signals are transmitted to the brain and translated into images. Lens transparency is vital for maintaining function. The lens is formed through a transition from organelle-rich epithelial cells to organelle-free fiber cells. Lens cell differentiation, leading to the lack of organelles, provides an environment optimal for minimizing light scatter and maximizing the ability to focus light onto the retina. The process responsible for orchestrating lens cell differentiation has yet to be elucidated. In recent years, data has emerged that led our lab to hypothesize that autophagy is likely involved in lens cell maintenance, cell differentiation, and maintenance of lens transparency. As a first step towards testing this hypothesis, we used RT-PCR, western blot analysis, immunohistochemistry, confocal microscopy, and next generation RNA-Sequencing (RNA-Seq) to examine autophagy genes expressed by the lens to begin mapping their lens function.

The function and role of PAK6, serine/threonone kinase, in cancer progressionhas not yet been clearly identified. Several studies reveal that PAK6 may participate in key changes contributing to cancer progression such as cell survival, cell motility, and invasiveness. Basedon the membrane localization of PAK6 in prostate and breast cancer cells,we speculated that PAK6 plays a rolein cancer progression cells by localizing on the membrane and modifying proteins linked to motility and proliferation. We isolated the raft domain of breast cancer cells expressing either wild type (WT), constitutively active (SN), or kinase dead PAK6 (KM) and found that PAK6 is a membrane associated kinase which translocates from the plasma membrane to the cytosol when activated. The downstream effects of PAK6 are unknown ; however, results from cell proliferation assays suggest a growth regulatory mechanism.

The assembly and maintenance of central synapses is a complex process, requiring myriad genes and their products. Highwire is a large gene containing a RING domain, characteristic of ubiquitin E3 ligases. Highwire has been shown to restrain axon growth and control synaptogenesis at a peripheral synapse. Here I examine the roles of Highwire at a central synapse in the adult Drosophila Giant Fiber System (GFS). Highwire is indeed necessary for proper axonal growth as well as synaptic transmission in the GFS. Differences arise between the central synapse and the neuromuscular junction (NMJ), where highwire was initially characterized : expresion from the postsynaptic cell can rescue highwire synaptic defects, which is not seen at the NMJ. In addition, a MAP kinase signaling pathway regulated by highwire at the NMJ has differing roles at a central synapse. Wallenda MAPK can rescue not only the highwire anatomical phenotype but also the defects seen in transmission. Another distinction is seen here : loss of function basket and Dfos enhance the highwire anatomical phenotype while expression of dominant negative basket and Dfos suppress the highwire phenotype. As a result we have compared the signaling pathway in flies and worms and found that the NMJ in the two organisms use a parallel pathway while the central synapse uses a distinct pathway.