Chapter 25: The Cytoskeleton I: Actin and Microfilaments Back To Chapter

25.7: Cytoskeletal Proteins in Bacteria

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Cytoskeletal Proteins in Bacteria

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Bacterial cells have diverse cytoskeletal proteins including eukaryotic homologs of actin, tubulin, and intermediate filaments, along with a unique fourth group, the MinD-ParA proteins.

Actin homologs, MreB and Mbl are found abundantly in rod and spiral-shaped bacteria. These proteins form spiral scaffolds that guide the formation of the peptidoglycan cell wall.

Another actin homolog, ParM, is encoded by non-genomic antibiotic-resistant plasmids in some bacteria and spontaneously assembles into filaments.

During cell division, the growing filament polymers push the plasmid copies apart to the opposite ends of the cell.

Tubulin homologs, FtsZ and BtubA/B, polymerize into filaments or rings.

FtsZ filaments assemble into the Z-ring at the middle of the cell to initiate cell division.

Crescentin subunits are the only intermediate filament-like proteins identified in bacteria. They create a crescent shape in some bacteria like Caulobacter crescentus. In the absence of crescentin subunits, these bacteria turn rod-shaped.

MinD and ParA are ATPases unique to bacterial cells and are required for cell division.

25.7: Cytoskeletal Proteins in Bacteria

Bacterial cells were initially considered simple, randomly organized structures lacking a cytoskeleton. However, the discovery of cytoskeleton homologs in bacteria led to the change of this opinion. Bacterial cytoskeletal filaments regulate the cell shape, cell polarity, cell division, and partitioning of plasmids during cell division. It was later discovered that bacterial cytoskeletal proteins, mainly actin and tubulin homologs, are diverse compared to their eukaryotic counterparts. On the other hand, intermediate filaments are extremely rare, with only a single homolog Crescentin, being reported.

Bacterial Actin

Bacterial actins, as per their gene sequences, are known to be highly diverse. They are classified into distinct families based on phylogenetic analysis, structural features, and functional similarities. Bioinformatics analysis has led to the classification of up to 35 different families of bacterial actin. Structural variations in bacterial actin filaments include—a dramatic change in the twist, where the intersubunit angles vary by around +/- 10^o in a filament; changes in strand number; and the possibility of antiparallel strands. These differences in filament structure ultimately lead to differences in filament dynamics and, thereby, their function. Despite their diversity, the important point is that the individual subunits have a similar tertiary structure and evolved from the same ancestor as eukaryotic actins.

Bacterial Tubulin

Microtubules formed from bacterial tubulin-like proteins are structurally different from the 13 protofilament structure common amongst most eukaryotes. Bacterial tubulins like FtsZ are known to form single-stranded filaments or twisted filament pairs instead of hollow tubes. Other homologs like BtubA/BtubB, mainly found in Prosthecobacter species, include a 5-protofilament structure. Although discovered later, it is hypothesized that bacterial microtubules came before the 13-protofilament eukaryotic structure, and longitudinal bonds in single-stranded filaments evolved before the lateral interaction required for the protofilament structure. And with the 5-protofilament structure found in Prosthecobacter species, the only reported bacterial protofilament is hypothesized to be an outcome of horizontal gene transfer.

Suggested Reading

25.7: Cytoskeletal Proteins in Bacteria

Chapter 1: Cells, Genomes, and Evolution

Chapter 2: Biochemistry of the Cell

Chapter 3: Energy and Catalysis

Chapter 4: Introduction to Metabolism

Chapter 5: Protein Structure

Chapter 6: Protein Function

Chapter 7: Structure and Organization of DNA

Chapter 8: DNA Replication and Repair

Chapter 9: Transcription: DNA to RNA

Chapter 10: Translation: RNA to Protein

Chapter 11: Control of Gene Expression

Chapter 12: Membrane Structure and Components

Chapter 13: Membrane Transport and Active Transporters

Chapter 14: Channels and the Electrical Properties of Membranes

Chapter 15: Transmembrane Transport in Endoplasmic Reticulum and Peroxisomes

Chapter 16: Intracellular Compartments and Protein Sorting

Chapter 17: Intracellular Membrane Traffic

Chapter 18: Endocytosis and Exocytosis

Chapter 19: Mitochondria and Energy Production

Chapter 20: Chloroplasts and Photosynthesis

Chapter 21: Principles of Cell Signaling

Chapter 22: Signaling Networks of G Protein-coupled Receptors

Chapter 23: Signaling Networks of Kinase Receptors

Chapter 24: Alternative Signaling Routes in Gene Expression

Chapter 25: The Cytoskeleton I: Actin and Microfilaments

Chapter 26: The Cytoskeleton II: Microtubules and Intermediate Filaments

Chapter 27: Extracellular Matrix in Animals

Chapter 28: Cell-Matrix Interactions

Chapter 29: Cell-Cell Interactions

Chapter 30: Cell Polarization and Migration

Chapter 31: Plant Cell Structure and Organization

Chapter 32: Analyzing Cells and Proteins

Chapter 33: Visualizing Cells, Tissues, and Molecules

Chapter 34: Cell Proliferation

Chapter 35: Cell Division

Chapter 36: Meiosis

Chapter 37: Cell Death

Chapter 38: Cancer

Chapter 39: Stem Cell Biology And Renewal in Epithelial Tissue

Chapter 40: A Hierarchical Stem-Cell System: Blood Cell Formation

Chapter 41: Fibroblast Transformation and Muscle Stem Cells

Chapter 42: Regeneration and Repair

Chapter 43: Embryonic and Induced Pluripotent Stem Cells

25.7: Cytoskeletal Proteins in Bacteria

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