Adhesion Molecules-28

Aging-9

Agricultural Biotechnology-37

Angiogenesis-29

Antisense-4

Apoptosis-49

Atherosclerosis-12

Autoimmunity-69

Bacterial Virulence-18

Bioinformatics-13

BioMaterials-18

Biotechnology-84

Cancer Genetics-25

Cancer Metastasis-19

Cell Biology-16

Cell Cycle-34

Cell Metabolism-327

Channels and Transporters-79

Chaperones-11

Circadian Rhythms-13

Coagulation-14

Cytokines/Growth Factors-52

Development-223

DNA-56

DNA Surveillance and Repair-41

Drug Design-17

Endocrine-66

Evolution-28

Extracellular Matrix-30

Gastroenterology-52

Gene Expression-178

Gene Therapy-53

Heart-61

Heat Shock Proteins-19

Hematology-11

Immunology-92

Infectious Disease-73

Ischemia-Reperfusion-33

MHC-17

Mitochondria-17

Nanomedicine-30

Neurodegenerative Disease-72

Neuropharmacology-112

Neuroscience-38

Nucleus-15

Oncogenes-8

Oncology-87

Parasitic Disease-12

Pharmacogenomics-14

Protein Superfamilies-11

Reproductive Biology-59

RNA-152

Signal Transduction-184

Stem Cells-80

Surgery-31

T-Cell Activation-12

Tissue Engineering-116

Transplant-50

Vaccines-82

Viruses-85

Chapter category:

Evolution of Telomere Binding Proteins

Chapter authors:
Martin P. Horvath

Telomere binding proteins provide essential functions for chromosome maintenance in most eukaryotes and consequently are well suited for analysis in the context of evolution. This review focuses on patterns gleaned from structural and functional characterization of telomere proteins that reveal contrasting evolutionary histories for double‑stranded and single‑stranded DNA‑binding protein families. The myb‑like/homeodomain DNA‑binding motif is ubiquitous among members of the double‑stranded telomere DNA‑binding protein family which includes Rap1 and Taz1 in yeast, TRF1 and TRF2 in vertebrates, as well as putative plant‑specific telomere proteins, TBP1, TRP1 and Smh1. In this myb‑motif family, strong purifying selection has preserved amino‑acid sequence among distantly related lineages. Accessory domains linked with the myb‑like DNA‑binding domain define distinct lineages, indicating that the myb motif was probably recruited multiple times from a reserve of more ancestral forms functioning as transcription factors. The oligonucleotide/oligosaccharide/oligopeptide‑binding (OB)‑fold is universally found in members of the second class of telomere binding proteins that recognize and bind T/G‑rich telomere sequences in the form of single‑stranded DNA. Examples of proteins in this class include TEBP‑α and TEBP‑β from ciliated protozoa, Cdc13 from budding yeast, and Pot1 which is widely distributed in fission yeast, vertebrates and plants. For these OB‑fold proteins, rapid divergence at the amino‑acid sequence level has all but erased traces of common ancestry. Homology is apparent, however, when comparing three‑dimensional structures and functional characters. Sequence alignments consistent with these structural comparisons provide a tentative glimpse of deeply rooted lineages that likely emerged from the general single‑stranded DNA‑binding proteins dedicated to DNA replication and repair. Interaction networks among telomere DNA‑binding proteins and their associated interacting partners hint at further common patterns and innovations encountered during the evolution of telomere capping complexes.

Martin P. Horvath
Biology Department, University of Utah, Salt Lake City, Utah USA

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