A Unified Multitude : Experimental Studies of Bacterial Chromosome Organization

Garmendia, Eva

January 2017

Bacteria are many, old and varied; different bacterial species have been evolving for millions of years and show many disparate life-styles and types of metabolism. Nevertheless, some of the characteristics regarding how bacteria organize their chromosomes are relatively conserved, suggesting that they might be both ancient and important, and that selective pressures inhibit their modification. This thesis aims to study some of these characteristics experimentally, assessing how changes affect bacterial growth, and how, after changing conserved features, bacteria might evolve. First, we experimentally tested what are the constraints on the horizontal transfer of a gene highly important for bacterial growth. Second, we investigated the significance of the location and orientation of a highly expressed and essential operon; and we experimentally evolved strains with suboptimal locations and orientations to assess how bacteria could adapt to these changes. Thirdly, we sought to understand the accessibility of different regions of the bacterial chromosome to engage in homologous recombination. And lastly, we constructed bacterial strains with chromosomal inversions to assess what effect the inversions had on growth rate, and how bacteria carrying costly inversions could evolve to reduce these costs. The results provide evidence for different selective forces acting to conserve these chromosome organizational traits. Accordingly, we found that evolutionary distance, functional conservation, suboptimal expression and impaired network connectivity of a gene can affect the successful transfer of genes between bacterial species. We determined that relative location of an essential and highly expressed operon is critical for supporting fast growth rate, and that its location seems to be more important than its orientation. We also found that both the location, and relative orientation of separated duplicate sequences can affect recombination rates between these sequences in different regions of the chromosome. Finally, the data suggest that the importance of having the two arms of a circular bacterial chromosome approximately equal in size is a strong selective force acting against certain type of chromosomal inversions.

bacterial evolution

chromosome organization and structure

chromosomal inversions

EF-Tu

horizontal gene transfer

Microbiology

Mikrobiologi

Genetics

Genetik

Evolutionary Biology

Evolutionsbiologi

The Importance of Bacterial Replichore Balance

Cerit, Ender Efe

January 2021

In most bacterial pathogens, the genome is comprised within a single circular chromosome which is typically organized by the origin-to-terminus axis that divides the chromosome into equally-sized arms of replication (replichores). This similarity in length is presumed to be required for the synchronization of the two replication forks to meet at the terminus for efficient chromosome segregation. Transfer of genes between organisms, different from the route of parent to offspring, is called horizontal gene transfer (HGT). Acquiring foreign DNA through HGT is an important factor for the evolution of virulence in bacteria since it provides access to new features such as new toxins and antibiotic resistance genes. Chromosomes of many pathogenic bacteria such as Salmonella spp. carry such horizontally-transferred DNA fragments called pathogenicity islands. However, after such HGT events, the existing organization of chromosome can be disrupted and an imbalance between the two halves of the circular chromosome might occur. The predicted outcome of a replichore imbalance is the retardation of growth which in turn might result in the out-competition by other faster-growing bacteria in the environment. For that reason, we have investigated the association of the fitness cost and the replichore imbalance with isogenic strains with varying degrees of inter-replichore inversions. Our results showed that there is a correlation between the magnitude of replichore imbalance and fitness cost, for example 2.49-fold imbalance (one replichore 2.49-fold longer than the other) resulted in 11% reduction of fitness in comparison with balanced replichores. Therefore, our data suggest that the replichore imbalance could be utilized to predict the fitness cost of HGT events.

Salmonella

bacterial evolution

fitness cost

chromosome organization and structure

chromosomal inversion

replichore

horizontal gene transfer

Microbiology in the medical area