Metabolic profile of myosin heavy chain-based fiber types in the rat soleus after spinal cord transection

Otis, Jeffrey Scott

14 November 2000

Fully differentiated muscle fibers can undergo considerable phenotypic changes in order to adjust to changing conditions of the physiological environment. It is generally accepted that the electrical impulses a muscle receives play a role in modulating the quantities of metabolic proteins (glycolytic and oxidative enzymes) and types of contractile proteins (myosin heavy chain, MHC) that are expressed. Research has shown that decreased neuromuscular activation following spinal cord transection (ST) results in adaptations in the physiological characteristics of paralyzed muscles, including atrophy and an accompanying loss of force production, and transformations of contractile and metabolic proteins toward a more fatigable state. However, it remains unclear whether or not a strong interdependence of energy metabolism and MHC isoform composition persists. Therefore, the goal of this study was to identify and quantify relative myosin heavy chain (MHC) isoform expression and metabolic enzyme profile adaptations at multiple time points (1, 3 and 6 months) in soleus fibers of rats following spinal cord transection (ST). To accomplish this, female Sprague-Dawley rats (~150 g, n = 15) were subjected to complete transection of the spinal cord at a mid-thoracic level. Age and weight-matched, non-operated rats served as controls (n = 15). The soleus was processed for quantitative single fiber histochemical analyses for succinate dehydrogenase (SDH, oxidative marker) and a-glycerophosphate dehydrogenase (GPD, glycolytic marker) activities (~30 fibers/muscle) and immunohistochemical analysis for MHC isoform composition. The total number of soleus fibers analyzed was ~900. Oxidative capacity was increased in muscle fibers at all time points after ST. Specifically, SDH activity was significantly higher than controls by 142, 127 and 206% at 1, 3 and 6 months post-ST, respectively. ISDH, a measure of total oxidative power, also increased in muscle fibers at all time points after ST. For example, 6 months after ST ISDH activity was 93% higher than controls (91.8-3.8 vs. 47.6-0.9 OD x 10-3, respectively). Glycolytic capacity peaked one month after ST. Thereafter, glycolytic capacity of all fibers steadily declined. For example, by 6 months, GPD activity had declined by 76% compared to 1 month GPD activities (3.3-0.2 vs. 13.7-1.4 OD x 10-3, respectively). These data suggest that the increases in glycolytic capacity are transient as fibers transition toward a faster MHC phenotype and then return towards control levels as fibers of a given type become phenotypically stable. The GPD/SDH ratio, an index of metabolic substrate utilization, peaked at one month after ST (394-41) and significantly decreased at 3 months (224-10) and at 6 months (95-7) after ST. Therefore, a shift occurred such that a greater dependence on oxidative metabolism was apparent. These data suggest that the oxidative capacities of soleus muscle fibers are not compromised after ST. In fact, as the fibers transitioned toward faster MHC isoforms, the GPD/SDH ratio was maintained or decreased, suggesting a reliance on oxidative metabolism regardless of MHC isoform composition. This might imply a dissociation between the contractile and metabolic characteristics of paralyzed soleus muscle fibers. However, these data are consistent with previous data and suggest that the increased fatigability observed after chronic reductions in neuromuscular activity are not due to compromised capacities for ATP synthesis. / Master of Science

GPD

SDH

spinal cord transection

myosin heavy chain

Inflammation and neuronal pathology in multiple sclerosis

Peterson, John Wesley

01 October 2003

No description available.

Multiple sclerosis

inflammation

demyelination

axonal transection

dendritic transection

neuronal apoptosis

neuronal pathology

microarray

gene chips

gene expression analysis

L'effet d'une variation du niveau d'activité physique sur les propriétés électrophysiologiques des motoneurones du nerf tibial chez le rat

Beaumont, Eric

January 2003

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Rats

Électrophysiologie

Motoneurone

Transection

Tissus foetal

Exercice passif

Entraînement volontaire

Entraînement en endurance

Intracellulaire

Décharge rythmique

Combining electrospun polydioxanone scaffolds, Schwann cells, and Matrigel to improve functional recovery after a complete spinal cord transection in rats

Kannan, Ashok

04 May 2012

Spinal cord injury (SCI) has presented itself as a multifaceted pathology that is largely inhibitory to regeneration, and therefore to functional recovery, even though spinal cord neurons have been found to be innately regenerative. Thus, having identified the key players in the inhibition of this innate regeneration, SCI researchers have focused on two major types of approaches: (1) blocking inhibitory cues and (2) promoting innate regeneration. Schwann cells (SCs) have long been shown to promote and enhance functional recovery after SCI through providing supplemental myelination and trophic and tropic factors to regenerating axons, though singular approaches rarely address the complex SCI pathology. Guidance channels and scaffolds have been shown to provide physical support and directional cues to regeneration axons. Therefore, a combinatorial approach in which SCs migrate into and throughout a guidance scaffold would be an ideal research focus for treating SCI. However, cell migration into guidance scaffolds has been shown to be problematic. This study attempts to assess and improve two- and three-dimensional SC migration on electrospun scaffolds. Additionally, we evaluate the ability of SCs, seeded on Matrigel-coated electrospun scaffolds, to improve functional recovery in rats with completely transected spinal cords.

Scaffold

Schwann cells

Matrigel

Spinal Cord Injury

Transection

Electrospinning

Anatomy

Medicine and Health Sciences

Nervous System

The Analysis of Brn3a and Thy1-CFP as Potential Markers of Retinal Ganglion Cells after Optic Nerve Injury in Mice

Levesque, Julie

28 May 2013

Purpose: Retinal ganglion cell (RGC) loss is a measure of the progression of many visual disorders. It is important to identify RGCs with good specificity, so RGC numbers can be reliably analyzed. The purpose of this study was to analyze the effectiveness of two current RGC markers: Brn3a immunohistochemistry and the expression of Thy1-CFP in the Thy1-CFP transgenic mouse. Methods: Rhodamine-?-isothiocyanate (RITC) retrograde labeling, immunohistochemistry, wholemount retinal imaging, western blot, cross sectional analysis and cell densities in uninjured control animals and 3, 5, 7 and 14 days post-optic nerve crush (ONC) or transection (ONT) were tabulated. Results: Brn3a positive (Brn3a+) cell density was significantly less than RITC positive (RITC+) cell density in control mice. After ON injury, Brn3a+ cell density did not decrease at the same rate as RITC+ cell density. The density of RGCs that express Brn3a was significantly less than the individual Brn3a+ and RITC+ cell density at all experimental time points. Thy1-CFP positive (Thy1-CFP+) cell density was significantly less than RITC+ in control mice and significantly more than RITC+ cell density 14 days after ON injury. Thy1-CFP co-localized with ChAT positive (ChAT+) cells 7 days after ONT. Conclusion: Brn3a and Thy1-CFP are not reliable markers of RGCs. Retrograde labeling remains one of the most reliable methods of labeling RGCs in mice.

retinal ganglion cell

retina

Thy1-CFP

optic nerve crush

optic nerve transection

mouse

transgenic

Brn3a

Neuronal Survival After Dendrite Amputation: Investigation of Injury Current Blockage

Shi, Ri Yi

12 1900

After dendrite transection, two primary injury current pathways may acount for cell death: (1) the lesion current at the site of injury and (2) the voltage sensitive calcium channels along the dendrite. Lesions were made with a laser microbeam in mouse spinal monolayer cell cultures. Polylysine was tried as a positively charged "molecular bandage" to block the lesion current. The calcium channel blockers, verapamil and nifedipine, were used to reduce the calcium channel current. Control toxicity curves were obtained for all three compounds. The results show that neither verapamil, nifedipine, nor polylysine (MW: 3,300) protect nerve cells after dendrite amputation 100 ptm from the soma. The data also indicate that these compounds do not slow the process of cell death after such physical trauma.

dendrite transection

cell death

nervous system

Neurons -- Physiology.

Nervous system -- Wounds and injuries.

Nervous system -- Degeneration.

Dendrites.

Thenar Muscle and Transverse Carpal Ligament Relationship

Loss, Jeremy Granieri

24 May 2019

No description available.

Biomedical Engineering

Biomechanics

Thenar muscle

Transverse carpal ligament

anatomy

TCL transection

Characterizing the regeneration of peripheral neurons: Re-innervation of the superior cervical ganglion

Walsh, Brian F.

07 May 2010

No description available.

Biology

Neurology

deafferentation

preganglionic transection

cholinergic

choline acetyltransferase

ChAT

superior cervical ganglion

SCG

Mechanisms controlling the cell body response to axon injury in dorsal root ganglion neurons

Bani Hammad, Rasheed Ahmed

22 June 2010

Successful axon regeneration appears to depend on the development of an injury response. Dorsal root ganglion neurons exemplify the necessity of this injury response in a unique way. Peripheral nerve transection leads to development of an injury response and successful regeneration whereas central root transection does neither. The injury response may involve extracellular and intracellular pathways. To investigate the extraneuronal influences, we performed nerve transection of either the central or peripheral axon branches and studied the expression of GAP-43, a key growth associated protein, and the transcription factors ATF3, c-Jun, and STAT3. Our results show that the responses to peripheral versus central nerve transection are fundamentally different. Peripheral but not central nerve transection increases GAP-43, ATF3, and c-Jun expression. STAT3, however, is upregulated as a result of central but not peripheral nerve transection. To investigate potential intracellular signalling pathways, we applied FGF-2, an extracellular mitogen, or an analog of cAMP, an intracellular second messenger to the cut end of the peripheral axon. Our results indicate that FGF-2 and cAMP act as activators of GAP-43 expression. On the other hand, FGF-2 and cAMP act to downregulate the expression of ATF3. FGF-2 upregulates c-Jun and the activated form of STAT3. Paradoxically, the regulation of GAP-43 expression by cAMP or by FGF-2 in vivo shows opposing results from the previously reported in vitro studies. Our present results suggest that the peripheral nerve injury response may be governed by at least three different signalling pathways.

STAT3

ATF3

cAMP

GAP-43

transcription factors

peripheral nerve injury

transection

dorsal root ganglion

sensory neurons

FGF-2

c-Jun

Mechanisms controlling the cell body response to axon injury in dorsal root ganglion neurons

Bani Hammad, Rasheed Ahmed

22 June 2010

Successful axon regeneration appears to depend on the development of an injury response. Dorsal root ganglion neurons exemplify the necessity of this injury response in a unique way. Peripheral nerve transection leads to development of an injury response and successful regeneration whereas central root transection does neither. The injury response may involve extracellular and intracellular pathways. To investigate the extraneuronal influences, we performed nerve transection of either the central or peripheral axon branches and studied the expression of GAP-43, a key growth associated protein, and the transcription factors ATF3, c-Jun, and STAT3. Our results show that the responses to peripheral versus central nerve transection are fundamentally different. Peripheral but not central nerve transection increases GAP-43, ATF3, and c-Jun expression. STAT3, however, is upregulated as a result of central but not peripheral nerve transection. To investigate potential intracellular signalling pathways, we applied FGF-2, an extracellular mitogen, or an analog of cAMP, an intracellular second messenger to the cut end of the peripheral axon. Our results indicate that FGF-2 and cAMP act as activators of GAP-43 expression. On the other hand, FGF-2 and cAMP act to downregulate the expression of ATF3. FGF-2 upregulates c-Jun and the activated form of STAT3. Paradoxically, the regulation of GAP-43 expression by cAMP or by FGF-2 in vivo shows opposing results from the previously reported in vitro studies. Our present results suggest that the peripheral nerve injury response may be governed by at least three different signalling pathways.

STAT3

ATF3

cAMP

GAP-43

transcription factors

peripheral nerve injury

transection

dorsal root ganglion

sensory neurons

FGF-2

c-Jun