Anatomic and transcriptomic characterization of the canola (Brassica napus) funiculus during seed development.

Chan, Ainsley

January 2013

Canola (Brassica napus) is a $19.3 billion industry for the Canadian economy annually, largely because of the demand for the oil derived from the seeds of this crop plant. Seed development and accumulation of important nutrients requires coordinated interactions between all seed regions, including the funiculus. The funiculus is a structure of the seed that serves as the only connection between the filial seed and the parent plant, yet its development and underlying transcriptional programs have not been explored. Using light and transmission electron microscopy, I completed an anatomical study of the funiculus over the course of development, from the mature ovule to the post-mature green seed stage. My results show that all three plant tissue systems of the funiculus undergo profound changes at the histological and ultrastructural level. To understand the programs that orchestrate these changes in the globular stage funiculus, I used laser microdissection coupled with RNA-sequencing. This produced a high-resolution dataset of the mRNAs present in each of the three tissue systems of the funiculus. Various clustering analyses and gene ontology term enrichment analysis identified several important biological processes associated with each tissue system. My data show that cell wall growth occurs in the epidermis, photosynthesis occurs in the cortex, and tissue proliferation and differentiation occurs in the vasculature. The importance of these processes in supporting overall seed growth and development is discussed, which can have profound implications in the genetic modification of the canola seed through manipulating the transcriptional activity of the funiculus.

canola

funiculus

seed

development

transcriptome

RNA-sequencing

Immune-to-brain communication driven by sterile lung injury

Litvin, David Gregory, Litvin

31 August 2018

No description available.

Physiology

Neurobiology

Biophysics

Sensorimotor behaviour in rats after lesions of dorsal spinal pathways

Kanagal, Srikanth Gopinath

05 September 2008

To investigate the roles of different dorsal spinal pathways in controlling movements in rats, I performed lesions of specific spinal pathways and measured the behaviour abilities of rats using different sensorimotor behavioural tests. The first experiment was designed to understand the contribution of sensory pathways traveling in the dorsal funiculus during locomotion and skilled movements using sensitive behavioural tests. I demonstrated that ascending sensory fibers play an important role during overground locomotion and contribute to skilled forelimb movements. The second experiment compared the differences in sensorimotor abilities caused by dorsal funicular lesions performed at two different levels of rat spinal cord. My results showed that the pathways present in the cervical and thoracic dorsal funiculus exert different functional effects over control of limb movement during locomotion. The third experiment investigated the compensatory potential of dorsal funicular pathways after dorsolateral funicular injuries in rats. My results showed that dorsal funicular pathways do not compensate for loss of dorsolateral pathways during the execution of locomotor tasks, though there is indirect evidence that rats with dorsolateral funicular lesions might rely more on ascending sensory pathways in the dorsolateral funiculus during skilled forelimb movements. Finally, the fourth experiment was designed to investigate the compensation from dorsolateral funicular pathways after injuries to pyramidal tract in rats. I demonstrated that pathways running in the spinal dorsolateral funiculus do provide compensatory input to spinal circuitry to maintain skilled reaching abilities after lesions of the pyramidal tract but these same pathways do not appear to compensate during either overground locomotion or skilled locomotion. Thus, this compensatory response is task-specific. These results highlight the fact that behavioural context determines the nature of compensation from spared pathways after spinal cord injuries.

Skilled forepaw usage

Task specific compensation

Compensation

Dorsolateral funiculus

Rubrospinal tract

Deficits

Dorsal funiculus

Single pellet reaching

Ascending sensory pathways

Corticospinal tract

Pyramidal tract

Rats

Spinal cord injury

Behaviour

Dorsal spinal pathways

Ground reaction forces

Overground locomotion

Horizontal ladder

Skilled locomotion

Sensorimotor behaviour in rats after lesions of dorsal spinal pathways

Kanagal, Srikanth Gopinath

05 September 2008

To investigate the roles of different dorsal spinal pathways in controlling movements in rats, I performed lesions of specific spinal pathways and measured the behaviour abilities of rats using different sensorimotor behavioural tests. The first experiment was designed to understand the contribution of sensory pathways traveling in the dorsal funiculus during locomotion and skilled movements using sensitive behavioural tests. I demonstrated that ascending sensory fibers play an important role during overground locomotion and contribute to skilled forelimb movements. The second experiment compared the differences in sensorimotor abilities caused by dorsal funicular lesions performed at two different levels of rat spinal cord. My results showed that the pathways present in the cervical and thoracic dorsal funiculus exert different functional effects over control of limb movement during locomotion. The third experiment investigated the compensatory potential of dorsal funicular pathways after dorsolateral funicular injuries in rats. My results showed that dorsal funicular pathways do not compensate for loss of dorsolateral pathways during the execution of locomotor tasks, though there is indirect evidence that rats with dorsolateral funicular lesions might rely more on ascending sensory pathways in the dorsolateral funiculus during skilled forelimb movements. Finally, the fourth experiment was designed to investigate the compensation from dorsolateral funicular pathways after injuries to pyramidal tract in rats. I demonstrated that pathways running in the spinal dorsolateral funiculus do provide compensatory input to spinal circuitry to maintain skilled reaching abilities after lesions of the pyramidal tract but these same pathways do not appear to compensate during either overground locomotion or skilled locomotion. Thus, this compensatory response is task-specific. These results highlight the fact that behavioural context determines the nature of compensation from spared pathways after spinal cord injuries.

Skilled forepaw usage

Task specific compensation

Compensation

Dorsolateral funiculus

Rubrospinal tract

Deficits

Dorsal funiculus

Single pellet reaching

Ascending sensory pathways

Corticospinal tract

Pyramidal tract

Rats

Spinal cord injury

Behaviour

Dorsal spinal pathways

Ground reaction forces

Overground locomotion

Horizontal ladder

Skilled locomotion