Characterization of the Cellular and Organellar Dynamics that Occur with a Partial Depletion of Mitochondrial DNA when Arabidopsis Organellar DNA Polymerase IB is Mutated

Cupp, John D.

07 August 2012

Plant mitochondrial genomes are large and complex, and the mechanisms for maintaining mitochondrial DNA (mtDNA) remain unclear. Arabidopsis thaliana has two DNA polymerase genes, polIA and polIB, that have been shown to be dual localized to mitochondria and chloroplasts but are unequally expressed within primary plant tissues involved in cell division or cell expansion. PolIB expression is observed at higher levels in both shoot and root apexes, suggesting a possible role in organelle DNA replication in rapidly dividing or expanding cells. It is proposed that both polIA and polIB are required for mtDNA replication under wild type conditions. An Arabidopsis T-DNA polIB mutant has a 30% reduction in mtDNA levels but also a 70% induction in polIA gene expression. The polIB mutant shows an increase relative to wild type plants in the number of mitochondria that are significantly smaller in relative size, observed within hypocotyl epidermis cells that have a reduced rate of cell expansion. These mutants exhibit a significant increase in gene expression for components of mitorespiration and photosynthesis, and there is evidence for an increase in both light to dark (transitional) and light respiration levels. There is not a significant difference in dark adjusted total respiration between mutant and wild type plants. Chloroplast numbers are not significantly different in isolated mesophyll protoplasts, but mesophyll cells from the mutant are significantly smaller than wild type. PolIB mutants exhibit a three-day delay in chloroplast development but after 7dpi (days post-imbibition) there is no difference in relative plastid DNA levels between the mutant and wild type. Overall, the polIB mutant exhibits an adjustment in cell homeostasis, which enables the maintenance of functional mitochondria but at the cost of normal cell expansion rates.

polymerase gamma

PolIA

PolIB

TWINKLE

mitochondria

DNA replication

Microbiology

Trypanosoma Brucei Mitochondrial DNA POLIB Cell Cycle Localization and Effect on POLIC when POLIB is Depleted

Rivera, Sylvia L

07 November 2016

Trypanosoma brucei is the causative agent of Human African Trypanosomiasis (HAT), also known as African sleeping sickness. T. brucei is unique in several ways that distinguish this organism from other eukaryotes. One of the unique features of T. brucei is the organism’s mitochondrial DNA, which is organized in a complex structure called kinetoplast DNA (kDNA). Since kDNA is unique to the kinetoplastids, kDNA may serve as a good drug target against T. brucei. Previews studies have shown that kDNA has 4 different family A mitochondrial DNA polymerases. Three of these mitochondrial DNA polymerases (POLIB, POLIC, and POLID) are essential components of kDNA synthesis and replication. POLID and POLIC dynamically localize throughout the cell cycle. POLID is found dispersed in the matrix before the kDNA has undergone replication and is re-localized at the antipodal sites when the kDNA is dividing. POLIC is found in the kinetoflagellar zone (KFZ) at low concentrations when the kDNA is not replicating and relocalizes to the antipodal sites when dividing. Based on the dynamic localization of these two DNA polymerases, we hypothesize that POLIB undergoes dynamic localization at some point during the cell cycle stage. Here, a POLIB/PTP single expressor cell line was analyzed by immunofluorescence microscopy in an unsynchronized population. We characterized the localization pattern of POLIB-PTP at different cell cycle stages and found different localization patterns throughout cell cycle. Cells at 1N1K (the majority of cell in an unsynchronized population) have single foci, but at 1N1Kdiv two different patterns are mainly observed, diffuse and segregated. When the kDNAs are separated POLIB-PTP is again seen as a distinct foci in each kDNA. By doing TdT labeling and a quantitative analysis, we found that at early stages of minicircles replication POLIB-PTP start relocalizing to the kDNA disk with a diffuse pattern being the main. By the time the minicircles are being reattached in the disk (late TdT), POLIB is seen in the disk as a bilobe shape.

T. brucei

POLIB

POLIC

polymerases

mitochondrial DNA

kDNA

Life Sciences

Microbiology

Pathogenic Microbiology