Glutamate transporter expression and localization are potently reg-

ulated by protein kinases. We used a kinome array platform to de-

termine global changes in serine-threonine kinase activity after

lateral fluid percussion in prefrontal cortex (PHC) and hippocampus

(HPC). In PFC 25 substrates had changes in phosphorylation status

greater or less than 1.15 fold change from sham while in HPC 15

substrates exhibited a 1.15 fold change difference from sham. Using

publically available algorithms and databases we mapped protein

kinases predicted to target substrate sequences and performed ran-

dom sampling permutation analyses to identify kinases targeting the

reporter peptides at frequencies greater than what would be expected

by chance. From kinases identified by the permutation analyses we

constructed signaling network models based on known direct inter-

actions in the Ingenuity database. We performed inhibitor studies in

the prefrontal cortex using the kinome array platform to further in-

vestigate the role of several kinases implicated by our analyses and

in the literature in TBI pathology. In pooled prefrontal cortical

samples, we found differential regulation of protein kinase B (AKT)

in the presence of the AKT inhibitor. In TBI samples, kinase activity

increased on array substrates in the presence of AKT inhibitor, while

kinase activity on substrates of the sham sample was decreased.

Kinase activity in the presence of c-Jun kinase inhibitor or combine

protein kinase C (PKC) and mitogen activated protein kinase kinase

(MEK) showed much less divergence in activity profiles. Of the

kinases identified in our analyses, AKT, PKC and protein kinase A

(PKA) are known to actively regulate glutamate transporter ex-

pression, localization and transport activity and suggest dysfuntion

in the balance of pro- and anti- glutamate reuptake mechanisms after

brain injury.

Keywords: kinase, cell signaling, glutamate transport, AKT

T1-12

ADIPOSE STROMAL VASCULAR FRACTION CELL

TREATMENT MITIGATES INCREASED CERE-

BROVASCULAR PERMEABILITY AFTER TRAUMATIC

BRAIN INJURY

Nino Muradashvili

1

, Reeta Tyagi

1

, Jacob Dale

3

, Richard L. Benton

2,4

,

Suresh C. Tyagi

1

, James B. Hoying

1,3

, David Lominadze

1,4

1

University of Louisville, Physiology and Biophysics, Louisville, USA

2

University of Louisville, Anatomical Sciences and Neurobiology,

Louisville, USA

3

University of Louisville, Cardiovascular Innovation Institute,

Louisville, USA

4

University of Louisville, Kentucky Spinal Cord Injury Research

Center, Louisville, USA

Traumatic brain injury (TBI) is accompanied by a loss of memory that

can be attributed to the formation of un-degradable complexes of

proteins such as fibrinogen (Fg) and cellular prion protein (PrP

C

). This

complex can be formed as a result of increased cerebrovascular per-

meability resulting in deposition of Fg in the interstitium. We tested

the hypothesis that adipose-derived stromal vascular fraction (SVF)

cells, that are anti-inflammatory and reparative, can mitigate TBI-

induced hyper-permeability and, by decreasing Fg-PrP

C

complex

formation, reduce memory loss. SVF cells collected from syngeneic

mouse adipose tissue were intravenously injected into experimental

mice the next day after TBI. Mice in control group were injected with

vehicle alone. Ten days after TBI pial venular permeability was as-

sessed by measuring the extravascular accumulation of fluorescently-

labeled bovine serum albumin. Formation of Fg-PrP

C

complexes in

mouse brain vascular subendothelial matrix was assessed by immu-

nohistochemistry. The novel object recognition test (NORT) was used

to assess changes in short-term memory after TBI. Cerebrovascular

protein leakage was reduced in mice infused with SVF cells

(131

–

3%) as compared to that in mice infused with vehicle alone

(186

–

6%) after TBI. Accumulation of Fg and PrP

C

in the interstitium

was mitigated by SVF cell treatment. NORT results showed that there

was a tendency in reduction of memory loss in mice with SVF cells.

These results suggest that TBI-induced cerebrovascular hyper-

permeability to proteins can be ameliorated with SVF cells affecting

vascular endothelium and leading to reduction of Fg-PrP

C

complex

formation and short-term memory loss. Thus, our data indicate a novel

therapeutic role of SVF cells in treatment of vasculo-neuronal dys-

function after TBI.

NIH grants NS-084823 and P30 GM-103507

Keywords: Cerebrovascular permeability, Fibrinogen, Cellular

prion protein, Endothelial repair, Short-term memory

T1-13

NEURONAL PLASMALEMMAL PERMEABILITY/DENDRITIC

BEADING IN THE HIPPOCAMPUS FOLLOWING DIFFUSE

BRAIN INJURY IN SWINE

James Harris

1,2

, Kevin D. Browne

1,2

, John A. Wolf

1,2

, Douglas H.

Smith

2

, John E. Duda

1,3

, D. Kacy Cullen

1,2

1

Philadelphia Veterans Affairs Medical Center, Center for Neuro-

trauma, Neurodegeneration and Restoration, Philadelphia, USA

2

University of Pennsylvania, Center for Brain Injury and Repair,

Department of Neurosurgery, Philadelphia, USA

3

University of Pennsylvania, Department of Neurology, Philadelphia,

USA

Closed-head traumatic brain injury (TBI) is generally caused by

rapid angular acceleration/deceleration of the head, resulting in

strain fields throughout the brain. However, the neuroanatomical

distribution and loading thresholds of cells affected by these strain

fields remain poorly understood. Our objective was to characterize

the extent of immediate alterations in plasmalemmal permeability in

the hippocampus following inertial TBI in swine. Swine underwent a

closed-head rotational acceleration (single injury or two injuries

separated by 15 minutes or 7 days). To assess plasmalemmal com-

promise, Lucifer Yellow (LY), a small (457 Da) cell impermeant

dye, was administered into the lateral ventricles. Animals were

sacrificed within 15 minutes (LY injections), 8 hours, or 7 days post-

injury (n

=

29 total). We found acute plasmalemmal permeability,

predominantly neural cells. LY

+

cells were observed across different

hippocampal regions, including the hilar region, dentate granule

layer, and CA1 area. A decrease in NeuN immunoreactivity was

observed in a subset of LY

+

cells, suggesting altered NeuN expres-

sion could indicate stressed neurons. In addition to LY in somata and

neurites, morphological changes were observed via acute beading in

dendritic fields projecting from dentate granule neurons. The effect

was most pronounced following a single severe injury but also fol-

lowing repetitive mild injuries. Although mitochondrial dysfunction

is a potential cause of beading, mitochondrial fission labeling did not

co-localize with beading. Given the rapid onset of permeability and

beading, these are likely acute biophysical disruptions due to diffuse

strain fields. Ongoing analyses are assessing the neurophysiological,

inflammatory, and degenerative changes associated with these

structural responses. Understanding trauma-induced biophysical re-

sponses and pathophysiological progression is necessary to guide

development of therapeutics to ameliorate afflicted cell populations

following inertial TBI.

Keywords: traumatic brain injury, biomechanics, plasma mem-

brane, cell permeability

A-6