Abstract
BackgroundSpermatogenesis is the process by which germ cells develop into spermatozoa in the testis. Sperm protamines are small, arginine-rich nuclear proteins which replace somatic histones during spermatogenesis, allowing a hypercondensed DNA state that leads to a smaller nucleus and facilitating sperm head formation. In eutherian mammals, the protamine-DNA complex is achieved through a combination of intra- and intermolecular cysteine cross-linking and possibly histidine-cysteine zinc ion binding. Most metatherian sperm protamines lack cysteine but perform the same function. This lack of dicysteine cross-linking has made the mechanism behind metatherian protamines folding unclear.ResultsProtamine sequences from UniProt’s databases were pulled down and sorted into homologous groups. Multiple sequence alignments were then generated and a gap weighted relative entropy score calculated for each position. For the eutherian alignments, the cysteine containing positions were the most highly conserved. For the metatherian alignment, the tyrosine containing positions were the most highly conserved and corresponded to the cysteine positions in the eutherian alignment.ConclusionsHigh conservation indicates likely functionally/structurally important residues at these positions in the metatherian protamines and the correspondence with cysteine positions within the eutherian alignment implies a similarity in function. One possible explanation is that the metatherian protamine structure relies upon dityrosine cross-linking between these highly conserved tyrosines. Also, the human protamine P1 sequence has a tyrosine substitution in a position expecting eutherian dicysteine cross-linking. Similarly, some members of the metatherian Planigales genus contain cysteine substitutions in positions expecting plausible metatherian dityrosine cross-linking. Rare cysteine-tyrosine cross-linking could explain both observations.
Highlights
Spermatogenesis is the process by which germ cells develop into spermatozoa in the testis
Multiple sequence alignment (MSA) were generated for 145 eutherian sperm protamine Protamine 1 protein (P1), 16 eutherian sperm protamine Protamine 2 protein (P2), 95 metatherian sperm protamine, and 34 fish protamine sequences, all retrieved from the UniProt knowledgebase and aligned using MUSCLE 3.8.31 [21, 22]
In summary, the common patterns of sequence conservation between eutherian and metatherian protamine P1 sequence families support hypotheses for dityrosine cross-linking in the metatherian P1 protamines and a rare cysteine-tyrosine cross-linking in human sperm protamine P1
Summary
Spermatogenesis is the process by which germ cells develop into spermatozoa in the testis. DNA undergoes hypercondensation in order to form a smaller nucleus This is accomplished through the final replacement of a vast majority of somatic DNA histones (>90%) with one of three nuclear proteins; sperm-specific histones, protamine-like proteins, or protamines [1]. After hypercondensation of DNA mediated by protamines, a haploid male germ cell nucleus is formed, which is genetically inactive but just 1/20th the size of a somatic cell nucleus [2]. This reorganization of the spermatozoa DNA is thought to protect the paternal genome against oxidative damage [1, 3,4,5]
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